Method for Obtaining Request of Station, Access Point, and Station

ABSTRACT

Embodiments of the present invention disclose a method for obtaining a request of a station, an access point, and a station. The method includes sending, by an access point, a control frame to a station and receiving, by the access point, a request to send frame sent by each station according to the control frame. The method also includes performing, by the access point, resource scheduling on each station according to the received request to send frame.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.15/624,791, filed on Jun. 16, 2017, which is a continuation ofInternational Application No. PCT/CN2014/094221, filed on Dec. 18, 2014.All of the afore-mentioned patent applications are hereby incorporatedby reference in their entireties.

TECHNICAL FIELD

The present embodiments relates to the field of wireless local areanetwork technologies, and in particular, to a method for obtaining arequest of a station, an access point, and a station.

BACKGROUND

A base station in a WLAN (wireless local area network) is also referredto as an AP (access point). Currently, in a WLAN system, an OFDM(orthogonal frequency division multiplexing) technology is generallyused for transmission. However, to improve system efficiency,introduction of an uplink multi-users technology, such as an uplinkOFDMA (orthogonal frequency division multiple access) technology anduplink multi-user MIMO (Multiple-Input Multiple-Output) technology, isunder consideration into a standard. In the uplink multi-usertechnology, a problem that needs to be resolved is how the AP obtains anuplink data request of a STA (station).

Currently, there are multiple technologies for obtaining the uplink datarequest of the STA.

In a first technology, the uplink data request is obtained by means ofrandom competition. Because random competition does not need a centralstation to control a network, random competition has a simple structureand flexible networking and is widely applied to a distributed network.However, when system load is very large and competition increases,conflict avoidance is relatively difficult, and an access requirement ofa specific service cannot be met.

In a second technology, the uplink data request is obtained by means ofpolling. That is, the AP specifies multiple STAs to send uplink datarequests on specified sub-channels by means of OFDMA. Because it isunknown which STAs have cached data, polling is blindly performed. As aresult, system efficiency is reduced because the AP polls a largequantity of STAs that have no uplink data.

SUMMARY

Embodiments of the present invention provide a method for obtaining arequest of a station, an access point, and a station, so as to meet anaccess requirement of a specific service and avoid invalid feedbacksfrom a large quantity of station s, thereby improving system efficiency.

A first aspect of the embodiments of the present invention provides amethod for obtaining a request of a station, including sending, by anaccess point, a control frame to the station, where the control frameincludes device indication information and allocation information ofavailable channels, the device indication information is used toindicate a to-be-scheduled station, and the allocation informationincludes information about a used-for-scheduling channel allocated toeach to-be-scheduled station and information about a selectable randomcompetition channel allocated to a non-to-be-scheduled station. Themethod also includes receiving, by the access point, a request to sendframe sent by each station according to the control frame andperforming, by the access point, resource scheduling on each stationaccording to the received request to send frame.

In a first possible implementation of the first aspect, if the availablechannels include one idle channel, before the sending, by an accesspoint, a control frame to the station, the sending further includes:using, by the access point, a part of sub-channels of the idle channelas the used-for-scheduling channel, and using the other part of thesub-channels of the idle channel as the random competition channel.

In a second possible implementation of the first aspect, if theavailable channels include at least two idle channels, before thesending, by an access point, a control frame to the station, the methodfurther includes: using, by the access point, a part of the at least twoidle channels as the used-for-scheduling channel, and using the otherpart of the idle channels as the random competition channel.

With reference to the second possible implementation of the firstaspect, in a third possible implementation, if the available channelsinclude one preset primary channel and at least one secondary channel,the using, by the access point, a part of the at least two idle channelsas the used-for-scheduling channel, and using the other part of the idlechannels as the random competition channel includes: using, by theaccess point, the primary channel as the used-for-scheduling channel,and using the at least one secondary channel as the random competitionchannel.

In a fourth possible implementation of the first aspect, if theavailable channels include at least two idle channels, before thesending, by an access point, a control frame to the station, the methodfurther includes: using, by the access point, a part of sub-channels ofeach idle channel as the used-for-scheduling channel, and using theother part of the sub-channels of each idle channel as the randomcompetition channel.

With reference to any one of the first aspect, or the first to thefourth possible implementations of the first aspect, in a fifth possibleimplementation, the device indication information is further used toindicate the non-to-be-scheduled station.

With reference to any one of the first aspect, or the first to thefourth possible implementations of the first aspect, in a sixth possibleimplementation, before the sending, by an access point, a control frameto the station, the method further includes: selecting, by the accesspoint, the to-be-scheduled station from the station s according toservice priorities of the station s.

With reference to any one of the first aspect, or the first to the sixthpossible implementations of the first aspect, in a seventh possibleimplementation, the information about the selectable random competitionchannel is used to indicate the selectable random competition channel,and the selectable random competition channel is obtained by removingthe used-for-scheduling channel from the available channels.

A second aspect of the embodiments of the present invention provides amethod for obtaining a request of a station, including receiving, by thestation, a control frame sent by an access point, where the controlframe includes device indication information and allocation informationof available channels, the device indication information is used toindicate a to-be-scheduled station, and the allocation informationincludes information about a used-for-scheduling channel allocated toeach to-be-scheduled station and information about a selectable randomcompetition channel allocated to a non-to-be-scheduled station. Themethod also includes determining, by the station according to the deviceindication information, whether the station is the to-be-scheduledstation. Additionally, the method includes if yes, determining, by thestation, a corresponding used-for-scheduling channel according to theallocation information of the available channels, and sending a requestto send frame by using the determined used-for-scheduling channel or ifno, selecting, by the station, at least one idle channel or idlesub-channel from the random competition channel according to theallocation information of the available channels, and sending a requestto send frame by using the selected idle channel or idle sub-channel.

In a first possible implementation of the second aspect, if the stationis the to-be-scheduled station, before the determining, by the station,a corresponding used-for-scheduling channel according to the allocationinformation of the available channels, the method further includes:determining, by the station, that cached data exists on the station.

In a second possible implementation of the second aspect, the deviceindication information is further used to indicate thenon-to-be-scheduled station, and if the station is not theto-be-scheduled station, before the selecting, by the station, at leastone idle channel or idle sub-channel from the random competition channelaccording to the allocation information of the available channels, themethod further includes: determining, by the station according to thedevice indication information, that the station is thenon-to-be-scheduled station.

With reference to any one of the second aspect, or the first or thesecond possible implementation of the second aspect, in a third possibleimplementation, the method further includes: starting, by the station,waiting upon receiving the control frame, and performing, only whenwaiting duration is equal to preset duration, the step of sending arequest to send frame by using the determined used-for-schedulingchannel.

A third aspect of the embodiments of the present invention provides anaccess point, including: a sending module, configured to send a controlframe to a station, where the control frame includes device indicationinformation and allocation information of available channels, the deviceindication information is used to indicate a to-be-scheduled station,and the allocation information includes information about aused-for-scheduling channel allocated to each to-be-scheduled stationand information about a selectable random competition channel allocatedto a non-to-be-scheduled station; a receiving module, configured toreceive a request to send frame sent by each station according to thecontrol frame; and a scheduling module, configured to perform resourcescheduling on each station according to the received request to sendframe.

In a first possible implementation of the third aspect, if the availablechannels include one idle channel, the device further includes: a firstchannel allocation module, configured to use a part of sub-channels ofthe idle channel as the used-for-scheduling channel and use the otherpart of the sub-channels of the idle channel as the random competitionchannel.

In a second possible implementation of the third aspect, if theavailable channels include at least two idle channels, the devicefurther includes: a second channel allocation module, configured to usea part of the at least two idle channels as the used-for-schedulingchannel and use the other part of the idle channels as the randomcompetition channel.

With reference to the second possible implementation of the thirdaspect, in a third possible implementation, if the available channelsinclude one preset primary channel and at least one secondary channel,the second channel allocation module is specifically configured to: usethe primary channel as the used-for-scheduling channel, and use the atleast one secondary channel as the random competition channel.

In a fourth possible implementation of the third aspect, if theavailable channels include at least two idle channels, the devicefurther includes: a third channel allocation module, configured to use apart of sub-channels of each idle channel as the used-for-schedulingchannel and use the other part of the sub-channels of each idle channelas the random competition channel.

With reference to any one of the third aspect, or the first to thefourth possible implementations of the third aspect, in a fifth possibleimplementation, the device indication information is further used toindicate the non-to-be-scheduled station.

With reference to any one of the third aspect, or the first to thefourth possible implementations of the third aspect, in a sixth possibleimplementation, the device further includes: a selection module,configured to select the to-be-scheduled station from the station saccording to service priorities of the station s.

With reference to any one of the third aspect, or the first to the sixthpossible implementations of the third aspect, in a seventh possibleimplementation, the information about the selectable random competitionchannel is used to indicate the selectable random competition channel,and the selectable random competition channel is obtained by removingthe used-for-scheduling channel from the available channels.

A fourth aspect of the embodiments of the present invention provides astation, including: a receiving module, configured to receive a controlframe sent by an access point, where the control frame includes deviceindication information and allocation information of available channels,the device indication information is used to indicate a to-be-scheduledstation, and the allocation information includes information about aused-for-scheduling channel allocated to each to-be-scheduled stationand information about a selectable random competition channel allocatedto a non-to-be-scheduled station; a determining module, configured todetermine, according to the device indication information, whether thestation is the to-be-scheduled station; a processing module, configuredto determine a corresponding used-for-scheduling channel according tothe allocation information of the available channels if the determiningmodule determines that the station is the to-be-scheduled station; and asending module, configured to send a request to send frame by using thedetermined used-for-scheduling channel, so that the access pointperforms resource scheduling on the station according to the request tosend frame; where the processing module is further configured to: selectat least one idle channel or idle sub-channel from the randomcompetition channel according to the allocation information of theavailable channels if the determining module determines that the stationis not the to-be-scheduled station; and the sending module is furtherconfigured to: send a request to send frame by using the selected idlechannel or idle sub-channel.

In a first possible implementation of the fourth aspect, the devicefurther includes: a detection module, configured to: if the determiningmodule determines that the station is the to-be-scheduled station,detect whether cached data exists on the station; and if it is detectedthat cached data exists, trigger the processing module to determine thecorresponding used-for-scheduling channel according to the allocationinformation of the available channels.

In a second possible implementation of the fourth aspect, the deviceindication information is further used to indicate thenon-to-be-scheduled station, and if the station is not theto-be-scheduled station, the determining module is further configuredto: determine, according to the device indication information, whetherthe station is the non-to-be-scheduled station; and if it is determinedthat the station is the non-to-be-scheduled station, trigger theprocessing module to select the at least one idle channel or idlesub-channel from the random competition channel.

With reference to any one of the fourth aspect, or the first or thesecond possible implementation of the fourth aspect, in a third possibleimplementation, the sending module is further configured to: startwaiting when the receiving module receives the control frame, and send,by using the determined used-for-scheduling channel, the request to sendframe only when waiting duration is equal to preset duration.

A fifth aspect of the embodiments of the present invention furtherprovides an access point, where the access point includes a radio signaltransceiver apparatus, a memory, and a processor, where the memorystores a set of program code, and the processor is configured to invokethe program code stored in the memory, to perform the followingoperations: sending a control frame to a station, where the controlframe includes device indication information and allocation informationof available channels, the device indication information is used toindicate a to-be-scheduled station, and the allocation informationincludes information about a used-for-scheduling channel allocated toeach to-be-scheduled station and information about a selectable randomcompetition channel allocated to a non-to-be-scheduled station;receiving a request to send frame sent by each station according to thecontrol frame; and performing resource scheduling on each stationaccording to the received request to send frame.

A sixth aspect of the embodiments of the present invention furtherprovides a station, where the station includes a radio signaltransceiver apparatus, a memory, and a processor, where the memorystores a set of program code, and the processor is configured to invokethe program code stored in the memory, to perform the followingoperations: receiving, by the station, a control frame sent by an accesspoint, where the control frame includes device indication informationand allocation information of available channels, the device indicationinformation is used to indicate a to-be-scheduled station, and theallocation information includes information about a used-for-schedulingchannel allocated to each to-be-scheduled station and information abouta selectable random competition channel allocated to anon-to-be-scheduled station; determining, by the station according tothe device indication information, whether the station is theto-be-scheduled station; and if yes, determining, by the station, acorresponding used-for-scheduling channel according to the allocationinformation of the available channels, and sending a request to sendframe by using the determined used-for-scheduling channel; or if no,selecting, by the station, at least one idle channel or idle sub-channelfrom the random competition channel according to the allocationinformation of the available channels, and sending a request to sendframe by using the selected idle channel or idle sub-channel.

A seventh aspect of the embodiments of the present invention furtherprovides a computer storage medium, where the computer storage mediumstores a program, and during execution of the program, some or all ofthe steps of the method for obtaining a request of a station providedaccording to the first aspect are performed.

An eighth aspect of the embodiments of the present invention furtherprovides a computer storage medium, where the computer storage mediumstores a program, and during execution of the program, some or all ofthe steps of the method for obtaining a request of a station providedaccording to the second aspect are performed.

A ninth aspect of the embodiments of the present invention furtherprovides a system for obtaining a request of a station, where the systemincludes an access point and at least one station, where: the accesspoint is the access point according to the third aspect, the firstpossible implementation of the third aspect, the second possibleimplementation of the third aspect, the third possible implementation ofthe third aspect, the fourth possible implementation of the thirdaspect, the fifth possible implementation of the third aspect, the sixthpossible implementation of the third aspect, or the seventh possibleimplementation of the third aspect; and the station is the stationaccording to the fourth aspect, the first possible implementation of thefourth aspect, the second possible implementation of the fourth aspect,or the third possible implementation of the fourth aspect.

It can be learnt from the foregoing descriptions that, according to theembodiments of the present invention, a control frame is sent to astation, where the control frame includes device indication informationand allocation information of available channels, the device indicationinformation is used to indicate a to-be-scheduled station, and theallocation information includes information about a used-for-schedulingchannel allocated to each to-be-scheduled station and information abouta selectable random competition channel allocated to anon-to-be-scheduled station; and a request to send frame sent by eachstation according to the control frame is received. This can not onlymeet an access requirement of a specific service but also avoid invalidfeedbacks from a large quantity of station s, thereby improving systemefficiency.

BRIEF DESCRIPTION OF THE DRAWINGS

To describe the technical solutions in the embodiments of the presentinvention more clearly, the following briefly describes the accompanyingdrawings required for describing the embodiments. Apparently, theaccompanying drawings in the following description show merely someembodiments of the present invention, and persons of ordinary skill inthe art may still derive other drawings from these accompanying drawingswithout creative efforts.

FIG. 1 is a schematic diagram of a method for obtaining a request of astation according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of a hybrid single-channel access manneraccording to an embodiment of the present invention;

FIG. 3 is a schematic diagram of a hybrid multi-channel access manneraccording to an embodiment of the present invention;

FIG. 4 is a schematic diagram of another hybrid multi-channel accessmanner according to an embodiment of the present invention;

FIG. 5 is a schematic diagram of another method for obtaining a requestof a station according to an embodiment of the present invention;

FIG. 6 is a schematic diagram of still another method for obtaining arequest of a station according to an embodiment of the presentinvention;

FIG. 7 is a schematic diagram of yet another method for obtaining arequest of a station according to an embodiment of the presentinvention;

FIG. 8 is a schematic diagram of still yet another method for obtaininga request of a station according to an embodiment of the presentinvention;

FIG. 9 is a schematic diagram of a further method for obtaining arequest of a station according to an embodiment of the presentinvention;

FIG. 10 is a schematic structural diagram of an access point accordingto an embodiment of the present invention;

FIG. 11 is a schematic structural diagram of another access pointaccording to an embodiment of the present invention;

FIG. 12 is a schematic structural diagram of a station according to anembodiment of the present invention;

FIG. 13 is a schematic structural diagram of another station accordingto an embodiment of the present invention; and

FIG. 14 is a schematic structural diagram of a system for obtaining arequest of a station according to an embodiment of the presentinvention.

DETAILED DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS

The following clearly describes the technical solutions in theembodiments of the present invention with reference to the accompanyingdrawings in the embodiments of the present invention. Apparently, thedescribed embodiments are merely some but not all of the embodiments ofthe present invention. All other embodiments obtained by persons ofordinary skill in the art based on the embodiments of the presentinvention without creative efforts shall fall within the protectionscope of the present embodiments.

The embodiments of the present invention can be applied to a wirelesslocal area network. The wireless local area network may be a BSS (basicservice set) that includes an access point. It should be understoodthat, in a basic network structure of a WiFi (Wireless Fidelity) system,a network may include multiple basic service sets, and each basicservice set may include an AP (access point) and multiple STAs(stations) associated with the AP.

The AP is also referred to as a wireless access point, a hotspot, or thelike. The AP is an access point through which a mobile subscriberaccesses a wired network, and is mainly deployed inside homes,buildings, and campuses. A typical coverage radius is tens of meters toa hundred meters. Alternatively, the AP may be deployed outdoors. The APis equivalent to a bridge that connects the wired network and a wirelessnetwork. A main function of the AP is to connect wireless networkclients together and then connect the wireless network to the Ethernet.

Main standards used for the AP are the IEEE (Institute of Electrical andElectronics Engineers) 802.11 series. Specifically, the AP may be aterminal device with a WiFi chip or a network device with a WiFi chip.Optionally, the AP may be a device that supports the 802.11ax standard.Further optionally, the AP may be a device that supports multiple WLAN(wireless local area network) standards, for example, 802.11ac, 802.11n,802.11g, 802.11b, and 802.11a.

The STA may be a wireless communications chip, a wireless sensor, or awireless communications terminal, for example, a mobile phone thatsupports a WiFi communication function, a tablet computer that supportsa WiFi communication function, a set-top box that supports a WiFicommunication function, or a computer that supports a WiFi communicationfunction. Optionally, the station may support the 802.11ax standard.Further optionally, the station supports multiple WLAN standards, forexample, 802.11ac, 802.11n, 802.11g, 802.11b, and 802.11a.

Currently, one of bandwidths 20 MHz, 40 MHz, 80 MHz, and 160 MHz (80+80MHz) is used for the WLAN. However, because the present embodiments haveno inevitable relationship with an actual bandwidth of a single channelor actual bandwidths of multiple channels, another bandwidth may be usedin an implementation of the present embodiments. In the presentembodiments, descriptions are provided by using an example in which achannel whose bandwidth is 20 MHz is used as a single channel andmultiple 20 MHz channels are used as multiple channels.

The following further clarifies the present embodiments with referenceto specific embodiments. It should be understood that these embodimentsare merely intended to describe the present embodiments, but are notintended to limit the scope of the present embodiments. Allmodifications in equivalent forms made to the present embodiments bypersons skilled in the art after reading the present embodiments fallwithin the scope limited by the claims accompanying this application.

Referring to FIG. 1, FIG. 1 is a schematic diagram of a method forobtaining a request of a station according to an embodiment of thepresent invention. This embodiment of the present invention providesdescriptions from a perspective of an access point. As shown in FIG. 1,the method for obtaining a request of a station in this embodiment ofthe present invention may include the following steps.

S11: The access point sends a control frame to the station, where thecontrol frame includes device indication information and allocationinformation of available channels, the device indication information isused to indicate a to-be-scheduled station, and the allocationinformation includes information about a used-for-scheduling channelallocated to each to-be-scheduled station and information about aselectable random competition channel allocated to a non-to-be-scheduledstation.

The available channels may be continuous channels, or may be discretechannels. This is not limited in the present embodiments.

Optionally, the non-to-be-scheduled station may include a station in abasic service set except the to-be-scheduled station indicated by thedevice indication information. It is assumed that the basic service setincludes a STA 1, a STA 2, a STA 3, a STA 4, and a STA 5, and the deviceindication information indicates that the STA 1 and the STA 2 areto-be-scheduled station s. In this case, the STA 3, the STA 4, and theSTA 5 are non-to-be-scheduled station s. That is, the STA 3, the STA 4,and the STA 5 can access a channel by means of random competition.

Further, the device indication information is further used to indicatethe non-to-be-scheduled station, and the non-to-be-scheduled station isdetermined according to the device indication information. It is assumedthat the basic service set still includes the STA 1, the STA 2, the STA3, the STA 4, and the STA 5, and the device indication informationindicates that the STA 1 and the STA 2 are the to-be-scheduled station sand the STA 3 and the STA 4 are the non-to-be-scheduled station s. Thatis, the STA 5 cannot access a channel. A probability of data collisioncan be effectively controlled by controlling a quantity of station sthat participate in random competition. In this way, system efficiencyis further improved.

Optionally, the access point may select the to-be-scheduled station fromthe station s according to service priorities of the station s, and thenallocate a corresponding used-for-scheduling channel to eachto-be-scheduled station. The random competition channel is the availablechannels except the used-for-scheduling channel. Selecting ato-be-scheduled station according to the service priorities of thestation s ensures that an access requirement of a high-priority serviceis met.

If the available channels include one idle channel, that is, an idlechannel of 20 MHz, the access point may use a part of sub-channels ofthe idle channel as the used-for-scheduling channel, and use the otherpart of the sub-channels of the idle channel as the random competitionchannel. Division of the sub-channels may be defined by a standard, ormay be performed by the access point. This is not limited in the presentembodiments.

As shown in FIG. 2, it is assumed that the idle channel is divided intoeight sub-channels, a STA 1 and a STA 2 are the to-be-scheduled stations, and a STA 3 to a STA 6 are the non-to-be-scheduled station s. Theaccess point may use a sub-channel 1 as a used-for-scheduling channeland allocate the sub-channel 1 to the STA 1, use a sub-channel 2 as aused-for-scheduling channel and allocate the sub-channel 2 to the STA 2,and use the other sub-channels 3 to 8 as selectable random competitionchannels.

If the available channels include at least two idle channels, the accesspoint may use a part of the at least two idle channels as theused-for-scheduling channel, and use the other part of the idle channelsas the random competition channel.

Further, if the available channels include one preset primary channeland at least one secondary channel, the access point may use the primarychannel as the used-for-scheduling channel, and use the at least onesecondary channel as the random competition channel.

Still further, each of the at least two idle channels may includemultiple sub-channels. The access point may use all sub-channels of apart of the idle channels as the used-for-scheduling channels, and useall sub-channels of the other part of the idle channels as the randomcompetition channels.

For example, there are two idle channels. It is assumed that one of theidle channels is a primary channel, and the other idle channel is asecondary channel. As shown in FIG. 3, each idle channel is divided intoeight sub-channels, a STA 11 to a STA 18 are to-be-scheduled station s,and a STA 21 to a STA 27 are non-to-be-scheduled station s. The accesspoint may use eight sub-channels of the primary channel asused-for-scheduling channels and allocate the eight sub-channels of theprimary channel to the STA 11 to the STA 18 respectively, and use eightsub-channels of the secondary channel as selectable random competitionchannels.

If the available channels include at least two idle channels, the accesspoint may use a part of sub-channels of each idle channel as theused-for-scheduling channel, and use the other part of the sub-channelsof each idle channel as the random competition channel.

Still for example, there are two idle channels. It is assumed that oneof the idle channels is the primary channel, the other idle channel isthe secondary channel, and each idle channel is divided into eightsub-channels; a STA 11, a STA 12, a STA 21, and a STA 22 areto-be-scheduled station s, and a STA 13 to a STA 16 and a STA 23 to aSTA 26 are non-to-be-scheduled station s. In this case, the access pointmay allocate a used-for-scheduling channel in either of the followingtwo manners.

In a first manner, locations of used-for-scheduling sub-channels on eachidle channel are the same. As shown in FIG. 4, the access pointallocates a sub-channel 1 and a sub-channel 2 of the primary channel tothe to-be-scheduled stations the STA 11 and the STA 12, and similarly,allocates a sub-channel 1 and a sub-channel 2 of the secondary channelto the to-be-scheduled stations the STA 21 and the STA 22; the othersub-channels are used as the random competition channels.

In a second manner, locations of used-for-scheduling sub-channels oneach idle channel are different. For example, the access point allocatesa sub-channel 1 and a sub-channel 2 of the primary channel to theto-be-scheduled stations the STA 11 and the STA 12, and allocates asub-channel 3 and a sub-channel 4 of the secondary channel to theto-be-scheduled stations the STA 21 and the STA 22; the othersub-channels are used as the random competition channels.

The control frame may be shown in Table 1. The device indicationinformation may be represented by a Scheduled STAs field, and is used toindicate a to-be-scheduled station. For example, a STA 1 and a STA 2 areto-be-scheduled stations, and the Scheduled STAs field may includedevice identifier information of the STA 1 and the STA 2.

Frame control is used to indicate a frame type, such as a reservedframe. Receiver address (RA) is an address on a wireless medium, thatis, a destination address at which the control frame is received, thatis, an address of each station. Transmitter address (TA) is an addressat which the control frame is sent, that is, an address of the accesspoint. Frame check sequence (FCS) is an error check code and records acheck code of a frame, and a cyclic redundancy code (CRC)-32 technologymay be used.

In an optional implementation, the allocation information of theavailable channels may be indicated by using a Scheduled sub-channelsfield and a Random access sub-channels field. The Scheduled sub-channelsfield includes the information about the used-for-scheduling channelallocated to each to-be-scheduled station. For example, in FIG. 2, aScheduled STAs field indicates that a STA 1 and a STA 2 areto-be-scheduled station s. A Scheduled sub-channels field may indicatethat a sub-channel 1 is allocated to the STA 1 and a sub-channel 2 isallocated to the STA 2. A Random access sub-channels field includesinformation about a selectable random competition channel allocated to anon-to-be-scheduled station. For example, the Random access sub-channelsfield indicates that the other sub-channels 3 to 8 are used as randomcompetition channels.

TABLE 1 Frame RA TA Scheduled Scheduled Random access FCS controlsub-channels STAs sub-channels

In another optional implementation, the allocation information of theavailable channels may be indicated by using a Scheduled sub-channelsfield and an Available sub-channels field, as shown in Table 2. That is,the control frame does not explicitly indicate a random competitionchannel. The selectable random competition channel is obtained byremoving the used-for-scheduling channel from the available channels,that is, by removing a channel indicated by the Scheduled sub-channelsfield from channels indicated by the Available sub-channels field.

TABLE 2 Frame RA TA Available Scheduled Scheduled FCS controlsub-channels sub-channels STAs

S12: The access point receives a request to send frame sent by eachstation according to the control frame.

Specifically, after each station, for example, a target station,receives the control frame, the target station first determines,according to the device indication information, whether the targetstation is the to-be-scheduled station. If the target station is theto-be-scheduled station, the target station determines a correspondingused-for-scheduling channel according to the allocation information ofthe available channels, and sends the RTS frame (request to send frame)by using the determined used-for-scheduling channel.

If the target station is not the to-be-scheduled station, the targetstation selects at least one idle channel or idle sub-channel from therandom competition channel according to the allocation information ofthe available channels, and sends the request to send frame by using theselected idle channel or idle sub-channel.

S13: The access point performs resource scheduling on each stationaccording to the received request to send frame.

Specifically, a scheduling policy may be flexibly adjusted according toa status of the received request to send frames and an idleness statusof a sub-channel. It is assumed that the status of the request to sendframes received by the access point is shown in FIG. 2. Because requestto send frames sent by the STA 4 and the STA 5 collide, the access pointcannot normally receive the corresponding request to send frames. As aresult, the access point determines that the STA 4 and the STA 5 have nocached data, and allocates the sub-channel to another station. Theaccess point may use a CTS frame (clear to send frame) to instruct theSTA 1 to transmit Data 1 on the sub-channel 1 and the sub-channel 2,instruct the STA 2 to transmit Data 2 on the sub-channel 3 and thesub-channel 4, instruct the STA 3 to transmit Data 3 on the sub-channel5 and the sub-channel 6, and instruct the STA 6 to transmit Data 6 onthe sub-channel 7 and the sub-channel 8.

It should be noted that a specific sending format of the CTS (forexample, to send the CTS by using an entire bandwidth or a sub-channel)does not belong to the present embodiments and is not limited. Any otherimplementation is applicable to this embodiment of the presentinvention.

In the embodiment shown in FIG. 2, an access point may send a controlframe to a station, where the control frame includes device indicationinformation and allocation information of available channels, the deviceindication information is used to indicate a to-be-scheduled station,and the allocation information includes information about aused-for-scheduling channel allocated to each to-be-scheduled stationand information about a selectable random competition channel allocatedto a non-to-be-scheduled station. Dividing the available channels intothe used-for-scheduling channel and the random competition channel cannot only meet an access requirement of a specific service but also avoidinvalid feedbacks from a large quantity of station s, thereby improvingsystem efficiency.

Referring to FIG. 5, FIG. 5 is a schematic diagram of another method forobtaining a request of a station according to an embodiment of thepresent invention. This embodiment of the present invention providesdescriptions from a perspective of an access point. Available channelsin this embodiment of the present invention include one idle channel,that is, an idle channel of 20 MHz. As shown in FIG. 5, the method forobtaining a request of a station in this embodiment of the presentinvention may include the following steps.

S51: The access point selects a to-be-scheduled station from station saccording to service priorities of the station s.

It should be noted that, in this embodiment of the present invention,the access point selects the to-be-scheduled station according to theservice priorities of the station s. In another optional embodiment, theto-be-scheduled station may be selected in another manner, which may beadjusted according to an actual application. This is not limited in thepresent embodiments.

Optionally, a non-to-be-scheduled station may include a station in abasic service set except the to-be-scheduled station. It is assumed thatthe basic service set includes a STA 1, a STA 2, a STA 3, a STA 4, and aSTA 5, and the STA 1 and the STA 2 are to-be-scheduled station s. Inthis case, the STA 3, the STA 4, and the STA 5 are non-to-be-scheduledstation s.

Further, the access point may further control a quantity ofnon-to-be-scheduled station s. That is, not all station s other than theto-be-scheduled station can access a channel. It is assumed that thebasic service set still includes the STA 1, the STA 2, the STA 3, theSTA 4, and the STA 5, and the STA 1 and the STA 2 are to-be-scheduledstation s. The access point controls a quantity of non-to-be-scheduledstation s to be 2. In this case, one of the STA 3, the STA 4, and theSTA 5 cannot access a channel. It is assumed that the STA 3 and the STA4 are non-to-be-scheduled station s, that is, the STA 5 cannot accessthe channel. Controlling a quantity of devices participating in randomcompetition can effectively control a probability of data collision, soas to further improve system efficiency.

S52: The access point divides a single channel into multiplesub-channels, allocates a used-for-scheduling channel to theto-be-scheduled station, and uses the other part of the sub-channels ofthe single channel as a random competition channel.

As shown in FIG. 2, it is assumed that the single channel is dividedinto eight sub-channels. A STA 1 and a STA 2 are to-be-scheduled stations, and a STA 3 to a STA 5 are non-to-be-scheduled station s. The accesspoint may use a sub-channel 1 as a used-for-scheduling channel andallocate the sub-channel 1 to the STA 1, use a sub-channel 2 as aused-for-scheduling channel and allocate the sub-channel 2 to the STA 2,and use the other sub-channels 3 to 8 as the selectable randomcompetition channels.

S53: The access point sends a control frame to each station, where thecontrol frame includes device indication information and allocationinformation of the available channels, the device indication informationis used to indicate the to-be-scheduled station, and the allocationinformation includes information about a used-for-scheduling channelallocated to each to-be-scheduled station and information about aselectable random competition channel allocated to a non-to-be-scheduledstation.

The device indication information may be represented by a Scheduled STAsfield, and is used to indicate a to-be-scheduled station. For example,the STA 1 and the STA 2 are to-be-scheduled station s, and the ScheduledSTAs field may include device identifier information of the STA 1 andthe STA 2.

In an optional implementation, the allocation information of theavailable channels may be indicated by using a Scheduled sub-channelsfield and a Random access sub-channels field, as shown in Table 1. TheScheduled sub-channels field includes the information about theused-for-scheduling channel allocated to each to-be-scheduled station.For example, in FIG. 2, a Scheduled STAs field indicates that the STA 1and the STA 2 are to-be-scheduled station s. A Scheduled sub-channelsfield may indicate that the sub-channel 1 is allocated to the STA 1 andthe sub-channel 2 is allocated to the STA 2. A Random accesssub-channels field includes the information about the selectable randomcompetition channel allocated to the non-to-be-scheduled station. Forexample, the Random access sub-channels field indicates that the othersub-channels 3 to 8 are used as random competition channels.

In another optional implementation, the allocation information of theavailable channels may be indicated by using a Scheduled sub-channelsfield and an Available sub-channels field, as shown in Table 2. That is,the control frame does not explicitly indicate a random competitionchannel. The selectable random competition channel is obtained byremoving the used-for-scheduling channel from the available channels,that is, by removing a channel indicated by the Scheduled sub-channelsfield from channels indicated by the Available sub-channels field.

S54: The access point receives a request to send frame sent by eachstation according to the control frame.

Specifically, after each station, for example, a target station,receives the control frame, the target station first determines,according to the device indication information, whether the targetstation is the to-be-scheduled station. If the target station is theto-be-scheduled station, the target station determines a correspondingused-for-scheduling channel according to the allocation information ofthe available channels, and sends the request to send frame by using thedetermined used-for-scheduling channel.

If the target station is not the to-be-scheduled station, the targetstation selects at least one idle channel or idle sub-channel from therandom competition channel according to the allocation information ofthe available channels, and sends the request to send frame by using theselected idle channel or idle sub-channel.

S55: The access point performs resource scheduling on each stationaccording to the received request to send frame.

Specifically, a scheduling policy may be flexibly adjusted according toa status of the received request to send frames and an idleness statusof a sub-channel. It is assumed that the status of the request to sendframes received by the access point is shown in FIG. 2. Because requestto send frames sent by the STA 4 and the STA 5 collide, the access pointcannot normally receive the corresponding request to send frames. As aresult, the access point determines that the STA 4 and the STA 5 have nocached data, and allocates the sub-channel to another station. As shownin FIG. 2, the access point uses a clear to send frame to instruct theSTA 1 to transmit Data 1 on the sub-channel 1 and the sub-channel 2,instruct the STA 2 to transmit Data 2 on the sub-channel 3 and thesub-channel 4, instruct the STA 3 to transmit Data 3 on the sub-channel5 and the sub-channel 6, and instruct the STA 5 to transmit Data 5 onthe sub-channel 7 and the sub-channel 8.

It should be noted that a specific sending format of the CTS (forexample, to send the CTS by using an entire bandwidth or a sub-channel)does not belong to the present embodiments and is not limited. Any otherimplementation is applicable to this embodiment of the presentembodiments.

It can be understood that this embodiment provides only a case in whichthere are five STAs and eight sub-channels; in an actual case, there maybe more STAs and sub-channels. The access point may use multiple typesof scheduling algorithms, which may be selected according to an actualneed.

In the embodiment shown in FIG. 5, when an obtained available channel isa single channel, an access point may select a to-be-scheduled stationfrom station s according to service priorities of the station s,allocate a part of sub-channels to the to-be-scheduled station as aused-for-scheduling channel, and use the other part of the sub-channelsas a selectable random competition channel. This can not only meet anaccess requirement of a high-priority service but also avoid invalidfeedbacks from a large quantity of station s, thereby improving systemefficiency.

Referring to FIG. 6, FIG. 6 is a schematic diagram of still anothermethod for obtaining a request of a station according to an embodimentof the present invention. This embodiment of the present inventionprovides descriptions from a perspective of an access point. Availablechannels in this embodiment of the present invention include at leasttwo idle channels. As shown in FIG. 6, the method for obtaining arequest of a station in this embodiment of the present embodiments mayinclude the following steps.

S61: The access point selects a to-be-scheduled station from station saccording to service priorities of the station s.

It should be noted that, in this embodiment of the present invention,the access point selects the to-be-scheduled station according to theservice priorities of the station s. In another optional embodiment, theto-be-scheduled station may be selected in another manner, which may beadjusted according to an actual application. This is not limited in thepresent embodiments.

S62: The access point uses a part of the at least two idle channels as aused-for-scheduling channel, and uses the other part of the idlechannels as the random competition channel.

Further, if the available channels include one preset primary channeland at least one secondary channel, the access point may use the primarychannel as the used-for-scheduling channel, and use the at least onesecondary channel as the random competition channel.

Still further, each of the at least two idle channels may includemultiple sub-channels. The access point may use all sub-channels of apart of the idle channels as the used-for-scheduling channels, and useall sub-channels of the other part of the idle channels as the randomcompetition channels.

For example, there are two idle channels. It is assumed that one of theidle channels is a primary channel, and the other idle channel is asecondary channel. As shown in FIG. 3, each idle channel is divided intoeight sub-channels. A STA 11 to a STA 18 are to-be-scheduled station s,and a STA 21 to a STA 26 are non-to-be-scheduled station s. The accesspoint may use eight sub-channels of the primary channel asused-for-scheduling channels and allocate the eight sub-channels of theprimary channel to the STA 11 to the STA 18 respectively, and use eightsub-channels of the secondary channel as selectable random competitionchannels.

S63: The access point sends a control frame to each station, where thecontrol frame includes device indication information and allocationinformation of the available channels, the device indication informationis used to indicate the to-be-scheduled station, and the allocationinformation includes information about a used-for-scheduling channelallocated to each to-be-scheduled station and information about aselectable random competition channel allocated to a non-to-be-scheduledstation.

The device indication information may be represented by a Scheduled STAsfield, and is used to indicate a to-be-scheduled station. For example,the STA 11 to the STA 18 are to-be-scheduled station s, and theScheduled STAs field may include device identifier information of theSTA 11 to the STA 18.

In an optional implementation, the allocation information of theavailable channels may be indicated by using a Scheduled sub-channelsfield and a Random access sub-channels field, as shown in Table 1. TheScheduled sub-channels field includes the information about theused-for-scheduling channel allocated to each to-be-scheduled station.For example, in FIG. 3, a Scheduled STAs field indicates that the STA 11to the STA 18 are to-be-scheduled station s, and a Scheduledsub-channels field may indicate that all the sub-channels of the primarychannel are allocated to the to-be-scheduled station s respectively. ARandom access sub-channels field includes the information about theselectable random competition channel allocated to thenon-to-be-scheduled station. For example, the Random access sub-channelsfield indicates that all the sub-channels of the secondary channel areused as random competition channels.

In another optional implementation, the allocation information of theavailable channels may be indicated by using a Scheduled sub-channelsfield and an Available sub-channels field, as shown in Table 2. That is,the control frame does not explicitly indicate a random competitionchannel. The selectable random competition channel is obtained byremoving the used-for-scheduling channel from the available channels,that is, by removing a channel indicated by the Scheduled sub-channelsfield from channels indicated by the Available sub-channels field.

S64: The access point receives a request to send frame sent by eachstation according to the control frame.

Specifically, after each station, for example, a target station,receives the control frame, the target station first determines,according to the device indication information, whether the targetstation is the to-be-scheduled station. If the target station is theto-be-scheduled station, the target station determines a correspondingused-for-scheduling channel according to the allocation information ofthe available channels, and sends the request to send frame by using thedetermined used-for-scheduling channel.

If the target station is not the to-be-scheduled station, the targetstation selects at least one idle channel or idle sub-channel from therandom competition channel according to the allocation information ofthe available channels, and sends the request to send frame by using theselected idle channel or idle sub-channel.

S65: The access point performs resource scheduling on each stationaccording to the received request to send frame.

Specifically, a scheduling policy may be flexibly adjusted according toa status of the received request to send frames and an idleness statusof a sub-channel. It is assumed that the status of the request to sendframes received by the access point is shown in FIG. 3. Because stations corresponding to indications in request to send frames that are fedback on a sub-channel 3 and a sub-channel 6 of the primary channel haveno cached data, and because data on a sub-channel 2 of the secondarychannel collides with data on a sub-channel 6 of the secondary channel,the access point cannot normally receive corresponding request to sendframes. Therefore, the access point may allocate the sub-channel 3 andthe sub-channel 6 of the primary channel and the sub-channel 2 and thesub-channel 6 of the secondary channel to other station s. For specificallocation, refer to FIG. 3, and details are not described herein.

It should be noted that a specific sending format of the CTS (forexample, to send the CTS by using an entire bandwidth or a sub-channel)does not belong to the present embodiments and is not limited. Any otherimplementation is applicable to this embodiment of the presentinvention.

It can be understood that this embodiment provides only a case in whichthere are 14 STAs and two idle channels. In an actual case, there may bemore STAs and idle channels. The access point may use multiple types ofscheduling algorithms, which may be selected according to an actualneed.

In the embodiment shown in FIG. 6, when obtained available channelsinclude at least two idle channels, an access point may select ato-be-scheduled station from station s according to service prioritiesof the stations, use a part of the at least two idle channels as aused-for-scheduling channel, and use the other part of the idle channelsas a random competition channel. This can not only meet an accessrequirement of a high-priority service but also avoid invalid feedbacksfrom a large quantity of station s, thereby improving system efficiency.

Referring to FIG. 7, FIG. 7 is a schematic diagram of yet another methodfor obtaining a request of a station according to an embodiment of thepresent invention. This embodiment of the present invention providesdescriptions from a perspective of an access point. Available channelsin this embodiment of the present invention include at least two idlechannels. As shown in FIG. 7, the method for obtaining a request of astation in this embodiment of the present invention may include thefollowing steps.

S71: The access point selects a to-be-scheduled station from station saccording to service priorities of the station s.

It should be noted that, in this embodiment of the present invention,the access point selects the to-be-scheduled station according to theservice priorities of the station s. In another optional embodiment, theto-be-scheduled station may be selected in another manner, which may beadjusted according to an actual application. This is not limited in thepresent embodiments.

S72: The access point uses a part of sub-channels of each idle channelas a used-for-scheduling channel and uses the other part of thesub-channels of each idle channel as a random competition channel.

For example, there are two idle channels. It is assumed that one of theidle channels is a primary channel, the other idle channel is asecondary channel, and each idle channel is divided into sevensub-channels; a STA 11, a STA 12, a STA 21, and a STA 22 areto-be-scheduled station s, and a STA 13 to a STA 16 and a STA 23 to aSTA 26 are non-to-be-scheduled station s. In this case, the access pointmay allocate a used-for-scheduling channel in either of the followingtwo manners.

In a first manner, locations of used-for-scheduling sub-channels on eachidle channel are the same. As shown in FIG. 4, the access pointallocates a sub-channel 1 and a sub-channel 2 of the primary channel tothe to-be-scheduled stations the STA 11 and the STA 12, and similarly,allocates a sub-channel 1 and a sub-channel 2 of the secondary channelto the to-be-scheduled stations the STA 21 and the STA 22; the othersub-channels are used as the random competition channels.

In a second manner, locations of used-for-scheduling sub-channels oneach idle channel are different. For example, the access point allocatesa sub-channel 1 and a sub-channel 2 of the primary channel to theto-be-scheduled stations the STA 11 and the STA 12, and allocates asub-channel 3 and a sub-channel 4 of the secondary channel to theto-be-scheduled stations the STA 21 and the STA 22; the othersub-channels are used as the random competition channels.

S73: The access point sends a control frame to each station, where thecontrol frame includes device indication information and allocationinformation of the available channels, the device indication informationis used to indicate the to-be-scheduled station, and the allocationinformation includes information about a used-for-scheduling channelallocated to each to-be-scheduled station and information about aselectable random competition channel allocated to a non-to-be-scheduledstation.

The device indication information may be represented by a Scheduled STAsfield, and is used to indicate a to-be-scheduled station. For example,the STA 11, the STA 12, the STA 21, and the STA 22 are to-be-scheduledstation s, and the Scheduled STAs field may include device identifierinformation of the STA 11, the STA 12, the STA 21, and the STA 22.

In an optional implementation, locations of used-for-schedulingsub-channels on each idle channel are the same, and the allocationinformation of the available channels may be indicated by using anAvailable sub-channels field and a Position of scheduled sub-channelsfield, as shown in Table 3. The Available sub-channels field is used toindicate all idle channels in the available channels, and the Positionof Scheduled sub-channels field is used to indicate the locations of theused-for-scheduling sub-channels on each idle channel. As shown in FIG.4, the Position of scheduled sub-channels field indicates that asub-channel 1 and a sub-channel 2 of each idle channel are allocated toto-be-scheduled station s.

TABLE 3 Frame RA TA Available Position of Scheduled FCS controlsub-channels Scheduled STAs sub-channels

In another optional implementation, locations of used-for-schedulingsub-channels on each idle channel are different, and the allocationinformation of the available channels may be indicated by using acombination of multiple Available sub-channels fields and Position ofScheduled sub-channels fields. As shown in Table 4, for example,Available Channel 1, Scheduled sub-channels in channel 1, and ScheduledSTAs field in channel 1 are used to indicate that a sub-channel 1 of theprimary channel is allocated to the STA 1.

TABLE 4 Frame RA TA Available Scheduled Scheduled . . . AvailableScheduled Scheduled FCS control Channel 1 sub-channels STAs in Channel nsub-channels STAs in in channel 1 channel 1 in channel n channel n

S74: The access point receives a request to send frame sent by eachstation according to the control frame.

Specifically, after each station, for example, a target station,receives the control frame, the target station first determines,according to the device indication information, whether the targetstation is the to-be-scheduled station. If the target station is theto-be-scheduled station, the target station determines a correspondingused-for-scheduling channel according to the allocation information ofthe available channels, and sends the request to send frame by using thedetermined used-for-scheduling channel.

If the target station is not the to-be-scheduled station, the targetstation selects at least one idle channel or idle sub-channel from therandom competition channel according to the allocation information ofthe available channels, and sends the request to send frame by using theselected idle channel or idle sub-channel.

S75: The access point performs resource scheduling on each stationaccording to the received request to send frame.

Specifically, a scheduling policy may be flexibly adjusted according toa status of the received request to send frames and an idleness statusof a sub-channel. It is assumed that the status of the request to sendframes received by the access point is shown in FIG. 4. Because requestto send frames sent by a STA 14, a STA 15, a STA 25, and a STA 26collide, the access point cannot normally receive the correspondingrequest to send frames. As a result, the access point determines thatthe STA 14, the STA 15, the STA 25, and the STA 26 have no cached data,and allocates the sub-channel to another station. For specificallocation, refer to FIG. 4, and details are not described herein.

It should be noted that a specific sending format of the CTS (forexample, to send the CTS by using an entire bandwidth or a sub-channel)does not belong to the present embodiments and is not limited. Any otherimplementation is applicable to this embodiment of the presentinvention.

In the embodiment shown in FIG. 7, when obtained available channelsinclude at least two idle channels, an access point may select ato-be-scheduled station from station s according to service prioritiesof the station s, use a part of sub-channels of each idle channel as aused-for-scheduling channels and allocate them to the to-be-scheduledstations, and use the other part of the sub-channels of each idlechannel as a random competition channels. This can not only meet anaccess requirement of a high-priority service but also avoid invalidfeedbacks from a large quantity of station s, thereby improving systemefficiency.

Referring to FIG. 8, FIG. 8 is a schematic diagram of still yet anothermethod for obtaining a request of a station according to an embodimentof the present invention. This embodiment of the present inventionprovides descriptions from a perspective of a station. As shown in FIG.8, the method for obtaining a request of a station in this embodiment ofthe present invention may include the following steps.

S81: The station receives a control frame sent by an access point, wherethe control frame includes device indication information and allocationinformation of available channels, the device indication information isused to indicate a to-be-scheduled station, and the allocationinformation includes information about a used-for-scheduling channelallocated to each to-be-scheduled station and information about aselectable random competition channel allocated to a non-to-be-scheduledstation.

The station obtains, by means of snooping, the control frame sent by theaccess point. The information about the selectable random competitionchannel is used to indicate the selectable random competition channel.The selectable random competition channel may be obtained by removingthe used-for-scheduling channel from the available channels.

S82: The station determines, according to the device indicationinformation, whether the station is the to-be-scheduled station.

Assuming that the control frame received by the station is shown inTable 1, the station may determine, according to a Scheduled STAs field,whether the station is the to-be-scheduled station.

Specifically, the Scheduled STAs field may include identifierinformation of the to-be-scheduled station. If the identifierinformation includes identifier information of the station, the stationmay determine that the station is the to-be-scheduled station.

S83: If yes, the station determines a corresponding used-for-schedulingchannel according to the allocation information of the availablechannels, and sends a request to send frame by using the determinedused-for-scheduling channel.

It is assumed that the control frame, received by the station, shown inTable 1 is still used as an example. When the station determines,according to the Scheduled STAs field, that the station is theto-be-scheduled station, the station may determine, according to aScheduled sub-channels field, a used-for-scheduling channel allocated bythe access point to the station, and then send the request to send frameby using the determined used-for-scheduling channel.

Further, if the station is the to-be-scheduled station, the station mayfurther detect whether cached data exists on the station. The stationsends the request to send frame by using the determinedused-for-scheduling channel only if cached data exists on the station.

Still further, the station starts waiting upon receiving the controlframe, and sends the request to send frame only when waiting duration isequal to preset duration. For example, the preset duration is t, and thestation may start timing upon receiving the control frame. After thestation determines the corresponding used-for-scheduling channel, thestation may further detect whether the waiting duration reaches t. Ifno, the station does not send the request to send frame until thewaiting duration is equal to t.

The preset duration is may be duration specified by the access point.

S84: If no, the station selects at least one idle channel or idlesub-channel from the random competition channel according to theallocation information of the available channels, and sends the requestto send frame by using the selected idle channel or idle sub-channel.

If the station is not the to-be-scheduled station, the station mayselect at least one idle channel or idle sub-channel from the randomcompetition channel according to the allocation information of theavailable channels, and the station sends the request to send frame byusing the selected idle channel or idle sub-channel.

If a format of the control frame received by the station is shown inTable 1, that is, the allocation information of the available channelsis indicated by using the Scheduled sub-channels field and a Randomaccess sub-channels field, the station may obtain the selectable randomcompetition channel according to the Random access sub-channels field,so as to select the at least one idle channel or idle sub-channel fromthe random competition channel.

If a format of the control frame received by the station is shown inTable 2, that is, the allocation information of the available channelsis indicated by using a Scheduled sub-channels field and an Availablesub-channels field, the station may obtain the selectable randomcompetition channel by removing a channel indicated by the Scheduledsub-channels field from channels indicated by the Available sub-channelsfield, so as to select the at least one idle channel or idle sub-channelfrom the random competition channel.

If a format of the control frame received by the station is shown inTable 3 or Table 4, that is, the allocation information of the availablechannels is indicated by using an Available sub-channels field and aPosition of Scheduled sub-channels field, the station may determinelocations of used-for-scheduling channels on each idle channel accordingto the Position of Scheduled sub-channels field, then remove theused-for-scheduling channels at the corresponding locations on each idlechannel, and obtain the selectable random competition channel, so as toselect the at least one idle channel or idle sub-channel from the randomcompetition channel.

Further, the device indication information is further used to indicatethe non-to-be-scheduled station. If the station is not theto-be-scheduled station, the station may further determine, according tothe device indication information, whether the station is thenon-to-be-scheduled station. If yes, the station selects the at leastone idle channel or idle sub-channel from the random competitionchannel. Otherwise, the station does not send the request to send frame.

In the embodiment shown in FIG. 8, a station may receive a control framesent by an access point, and determine, according to device indicationinformation in the control frame, whether the station is ato-be-scheduled station; if yes, the station determines aused-for-scheduling channel; otherwise, the station selects at least oneidle channel or idle sub-channel from a random competition channel. Thiscan not only meet an access requirement of a high-priority service butalso avoid invalid feedbacks from a large quantity of station s, therebyimproving system efficiency.

Referring to FIG. 9, FIG. 9 is a schematic diagram of a further methodfor obtaining a request of a station according to an embodiment of thepresent invention. This embodiment of the present invention providesdescriptions from a perspective of a station. As shown in FIG. 9, themethod for obtaining a request of a station in this embodiment of thepresent invention may include the following steps.

S91: The station receives a control frame sent by an access point, wherethe control frame includes device indication information and allocationinformation of available channels, the device indication information isused to indicate a to-be-scheduled station and a non-to-be-scheduledstation, and the allocation information includes information about aused-for-scheduling channel allocated to each to-be-scheduled stationand information about a selectable random competition channel allocatedto the non-to-be-scheduled station.

The station obtains, by means of snooping, the control frame sent by theaccess point. The information about the selectable random competitionchannel is used to indicate the selectable random competition channel.The selectable random competition channel may be obtained by removingthe used-for-scheduling channel from the available channels.

S92: The station determines, according to the device indicationinformation, whether the station is the to-be-scheduled station.

Assuming that the control frame received by the station is shown inTable 1, the station may determine, according to a Scheduled STAs field,whether the station is the to-be-scheduled station.

Specifically, the Scheduled STAs field may include identifierinformation of the to-be-scheduled station. If the identifierinformation includes identifier information of the station, the stationmay determine that the station is the to-be-scheduled station.

S93: If the station is the to-be-scheduled station, the station detectswhether cached data exists on the station.

S94: If cached data exists on the station, the station determines acorresponding used-for-scheduling channel according to the allocationinformation of the available channels, and sends a request to send frameby using the determined used-for-scheduling channel.

It is assumed that the control frame, received by the station, shown inTable 1 is still used as an example. If the station detects that cacheddata exists, the station may determine, according to a Scheduledsub-channels field, a used-for-scheduling channel allocated by theaccess point to the station, and then send the request to send frame byusing the determined used-for-scheduling channel.

Further, the station starts waiting upon receiving the control frame,and sends the request to send frame only when waiting duration is equalto preset duration. For example, the waiting duration is t, and thestation may start timing upon receiving the control frame. After thestation determines the corresponding used-for-scheduling channel, thestation may further detect whether the waiting duration reaches t. Ifno, the station does not send the request to send frame until thewaiting duration is equal to t.

S95: If the station is not the to-be-scheduled station, the stationdetermines, according to the device indication information, whether thestation is the non-to-be-scheduled station.

A format of the control frame may be shown in Table 5. The deviceindication information may include a Scheduled STAs field and aNon-Scheduled STAs field. The Non-Scheduled STAs field is used toindicate the non-to-be-scheduled station. When the station determines,according to the Scheduled STAs field, that the station is not theto-be-scheduled station, the station may determine, according to theNon-Scheduled STAs field, whether the station is the non-to-be-scheduledstation.

TABLE 5 Frame RA TA Scheduled Scheduled Non- Random FCS control sub-STAs Scheduled access channels STAs sub- channels

S96: If the station is the non-to-be-scheduled station, the stationselects at least one idle channel or idle sub-channel from the randomcompetition channel according to the allocation information of theavailable channels, and sends a request to send frame by using theselected idle channel or idle sub-channel.

If a format of the control frame received by the station is shown inTable 1, that is, the allocation information of the available channelsis indicated by using the Scheduled sub-channels field and a Randomaccess sub-channels field, the station may obtain the selectable randomcompetition channel according to the Random access sub-channels field,so as to select the at least one idle channel or idle sub-channel fromthe random competition channel.

If a format of the control frame received by the station is shown inTable 2, that is, the allocation information of the available channelsis indicated by using a Scheduled sub-channels field and an Availablesub-channels field, the station may obtain the selectable randomcompetition channel by removing a channel indicated by the Scheduledsub-channels field from channels indicated by the Available sub-channelsfield, so as to select the at least one idle channel or idle sub-channelfrom the random competition channel.

If a format of the control frame received by the station is shown inTable 3 or Table 4, that is, the allocation information of the availablechannels is indicated by using an Available sub-channels field and aPosition of Scheduled sub-channels field, the station may determinelocations of used-for-scheduling channels on each idle channel accordingto the Position of Scheduled sub-channels field, then remove theused-for-scheduling channels at the corresponding locations on each idlechannel, and obtain the selectable random competition channel, so as toselect the at least one idle channel or idle sub-channel from the randomcompetition channel.

Further, the station starts waiting upon receiving the control frame,and sends the request to send frame only when waiting duration is equalto preset duration. For example, the waiting duration is t, and thestation may start timing upon receiving the control frame. After thestation selects the at least one idle channel or idle sub-channel fromthe random competition channel, the station may further detect whetherthe waiting duration reaches t. If no, the station does not send therequest to send frame until the waiting duration is equal to t.

S97: If cached data does not exist on the station or the station is notthe non-to-be-scheduled station, the station does not send a request tosend frame.

In the embodiment shown in FIG. 9, a station may determine, according todevice indication information in a control frame, whether the station isa to-be-scheduled station. If yes, the station determines aused-for-scheduling channel. If no, the station further determineswhether the station is a non-to-be-scheduled station. If yes, thestation selects at least one idle channel or idle sub-channel from arandom competition channel. An access point controls a quantity ofstation s that access a channel, so as to control a probability of datacollision. In this way, system efficiency is improved.

Referring to FIG. 10, FIG. 10 is a schematic structural diagram of anaccess point according to an embodiment of the present invention. Asshown in FIG. 10, the access point 10 in this embodiment of the presentinvention may include at least a sending module 101, a receiving module102, and a scheduling module 103.

The sending module 101 is configured to send a control frame to astation. The control frame includes device indication information andallocation information of available channels. The device indicationinformation is used to indicate a to-be-scheduled station. Theallocation information includes information about a used-for-schedulingchannel allocated to each to-be-scheduled station and information abouta selectable random competition channel allocated to anon-to-be-scheduled station.

The available channels may be continuous channels, or may be discretechannels. This is not limited in the present embodiments.

Optionally, the non-to-be-scheduled station may include a station in abasic service set except the to-be-scheduled station indicated by thedevice indication information. It is assumed that the basic service setincludes a STA 1, a STA 2, a STA 3, a STA 4, and a STA 5, and the deviceindication information indicates that the STA 1 and the STA 2 areto-be-scheduled station s. In this case, the STA 3, the STA 4, and theSTA 5 are non-to-be-scheduled station s. That is, the STA 3, the STA 4,and the STA 5 can access a channel by means of random competition.

Further, the device indication information is further used to indicatethe non-to-be-scheduled station, and the non-to-be-scheduled station isdetermined according to the device indication information. It is assumedthat the basic service set still includes the STA 1, the STA 2, the STA3, the STA 4, and the STA 5, and the device indication informationindicates that the STA 1 and the STA 2 are the to-be-scheduled station sand the STA 3 and the STA 4 are the non-to-be-scheduled station s. Thatis, the STA 5 cannot access a channel. A probability of data collisioncan be effectively controlled by controlling a quantity of station sthat participate in random competition. In this way, system efficiencyis further improved.

Optionally, the access point 10 may further include a selection module104, configured to select the to-be-scheduled station from the station saccording to service priorities of the station s.

Further, the information about the selectable random competition channelis used to indicate the selectable random competition channel. Theselectable random competition channel is obtained by removing theused-for-scheduling channel from the available channels.

If the available channels include one idle channel, the access point 10may further include a first channel allocation module 105, configured touse a part of sub-channels of the idle channel as theused-for-scheduling channel and use the other part of the sub-channelsof the idle channel as the random competition channel.

As shown in FIG. 2, it is assumed that the idle channel is divided intoeight sub-channels, a STA 1 and a STA 2 are to-be-scheduled station s,and a STA 3 to a STA 6 are non-to-be-scheduled station s. The firstchannel allocation module 105 may use a sub-channel 1 as aused-for-scheduling channel and allocate the sub-channel 1 to the STA 1,use a sub-channel 2 as a used-for-scheduling channel and allocate thesub-channel 2 to the STA 2, and use the other sub-channels 3 to 8 asselectable random competition channels.

If the available channels include at least two idle channels, the accesspoint 10 may further include a second channel allocation module 106,configured to use a part of the at least two idle channels as theused-for-scheduling channel and use the other part of the idle channelsas the random competition channel.

Further, if the available channels include one preset primary channeland at least one secondary channel, the second channel allocation module106 may be specifically configured to use the primary channel as theused-for-scheduling channel, and use the at least one secondary channelas the random competition channel.

Still further, each of the at least two idle channels may includemultiple sub-channels. The second channel allocation module 106 may useall sub-channels of a part of the idle channels as theused-for-scheduling channels, and use all sub-channels of the other partof the idle channels as the random competition channels.

For example, there are two idle channels. It is assumed that one of theidle channels is a primary channel, and the other idle channel is asecondary channel. As shown in FIG. 3, each idle channel is divided intoeight sub-channels, a STA 11 to a STA 18 are to-be-scheduled station s,and a STA 21 to a STA 27 are non-to-be-scheduled station s. The secondchannel allocation module 106 may use eight sub-channels of the primarychannel as used-for-scheduling channels and allocate the eightsub-channels of the primary channel to the STA 11 to the STA 18respectively, and use eight sub-channels of the secondary channel asselectable random competition channels.

If the available channels include at least two idle channels, the accesspoint 10 may further include a third channel allocation module 107,configured to use a part of sub-channels of each idle channel as theused-for-scheduling channel and use the other part of the sub-channelsof each idle channel as the random competition channel.

Still for example, there are two idle channels. It is assumed that oneof the idle channels is a primary channel, the other idle channel is asecondary channel, and each idle channel is divided into eightsub-channels; a STA 11, a STA 12, a STA 21, and a STA 22 areto-be-scheduled station s, and a STA 13 to a STA 16 and a STA 23 to aSTA 26 are non-to-be-scheduled station s. The third channel allocationmodule 107 may allocate a used-for-scheduling channel in either of thefollowing two manners.

In a first manner, locations of used-for-scheduling sub-channels on eachidle channel are the same. As shown in FIG. 4, the third channelallocation module 107 allocates a sub-channel 1 and a sub-channel 2 ofthe primary channel to the to-be-scheduled stations the STA 11 and theSTA 12, and similarly, allocates a sub-channel 1 and a sub-channel 2 ofthe secondary channel to the to-be-scheduled stations the STA 21 and theSTA 22; the other sub-channels are used as the random competitionchannels.

In a second manner, locations of used-for-scheduling sub-channels oneach idle channel are different. For example, the third channelallocation module 107 allocates a sub-channel 1 and a sub-channel 2 ofthe primary channel to the to-be-scheduled stations the STA 11 and theSTA 12, and allocates a sub-channel 3 and a sub-channel 4 of thesecondary channel to the to-be-scheduled stations the STA 21 and the STA22; the other sub-channels are used as the random competition channels.

The receiving module 102 is configured to receive a request to sendframe sent by each station according to the control frame.

The scheduling module 103 is configured to perform resource schedulingon each station according to the received request to send frame.

It can be understood that a function of each function module of theaccess point 10 in this embodiment can be specifically implementedaccording to the methods in the foregoing method embodiments. Forspecific descriptions, correspondingly refer to related descriptions ofthe method embodiments in FIG. 1 to FIG. 7, and details are notdescribed herein again.

Referring to FIG. 11, FIG. 11 is a schematic structural diagram ofanother access point according to an embodiment of the presentinvention. As shown in FIG. 11, the access point 11 may include at leastone processor 111, for example, a CPU, at least one communications bus112, a radio signal transceiver apparatus 113, and a memory 114. Theradio signal transceiver apparatus 113 is configured to receive and senda signal, such as a control frame or a clear to send frame. Thecommunications bus 112 is configured to implement connection andcommunication among these components. The memory 114 may be ahigh-speed, or may be a non-volatile memory (non-volatile memory), forexample, at least one magnetic disk memory. The memory 114 stores a setof program code. The processor 111 is configured to invoke the programcode stored in the memory 114, to perform the following operations:sending a control frame to a station by using the radio signaltransceiver apparatus 113, where the control frame includes deviceindication information and allocation information of available channels,the device indication information is used to indicate a to-be-scheduledstation, and the allocation information includes information about aused-for-scheduling channel allocated to each to-be-scheduled stationand information about a selectable random competition channel allocatedto a non-to-be-scheduled station; receiving, by using the radio signaltransceiver apparatus 113, a request to send frame sent by each stationaccording to the control frame; and performing resource scheduling oneach station according to the received request to send frame.

If the available channels include one idle channel, the processor 111may further perform the following operation before sending the controlframe to the station by using the radio signal transceiver apparatus113: using a part of sub-channels of the idle channel as theused-for-scheduling channel, and using the other part of thesub-channels of the idle channel as the random competition channel.

If the available channels include at least two idle channels, theprocessor 111 may further perform the following operation before sendingthe control frame to the station by using the radio signal transceiverapparatus 113: using a part of the at least two idle channels as theused-for-scheduling channel, and using the other part of the idlechannels as the random competition channel.

If the available channels include one preset primary channel and atleast one secondary channel, the using, by the processor 111, a part ofthe at least two idle channels as the used-for-scheduling channel, andusing the other part of the idle channels as the random competitionchannel may be specifically: using the primary channel as theused-for-scheduling channel, and using the at least one secondarychannel as the random competition channel.

If the available channels include at least two idle channels, theprocessor 111 may further perform the following operation before sendingthe control frame to the station by using the radio signal transceiverapparatus 113: using a part of sub-channels of each idle channel as theused-for-scheduling channel, and using the other part of thesub-channels of each idle channel as the random competition channel.

Optionally, the device indication information is further used toindicate the non-to-be-scheduled station.

Optionally, the processor 111 may further perform the followingoperation before sending the control frame to the station by using theradio signal transceiver apparatus 113: selecting the to-be-scheduledstation from the station s according to service priorities of thestation s.

Further, the information about the selectable random competition channelis used to indicate the selectable random competition channel. Theselectable random competition channel is obtained by removing theused-for-scheduling channel from the available channels.

It can be understood that a function of each function module of theaccess point 11 in this embodiment can be specifically implementedaccording to the methods in the foregoing method embodiments. Forspecific descriptions, correspondingly refer to related descriptions ofthe method embodiments in FIG. 1 to FIG. 7, and details are notdescribed herein again.

Referring to FIG. 12, FIG. 12 is a schematic structural diagram of astation according to an embodiment of the present invention. As shown inFIG. 12, the station 12 in this embodiment of the present invention mayinclude at least a receiving module 121, a determining module 122, aprocessing module 123, and a sending module 124.

The receiving module 121 is configured to receive a control frame sentby an access point, where the control frame includes device indicationinformation and allocation information of available channels, the deviceindication information is used to indicate a to-be-scheduled station,and the allocation information includes information about aused-for-scheduling channel allocated to each to-be-scheduled stationand information about a selectable random competition channel allocatedto a non-to-be-scheduled station.

The determining module 122 is configured to determine, according to thedevice indication information, whether the station is theto-be-scheduled station.

The processing module 123 is configured to determine a correspondingused-for-scheduling channel according to the allocation information ofthe available channels if the determining module 122 determines that thestation is the to-be-scheduled station.

The sending module 124 is configured to send a request to send frame byusing the determined used-for-scheduling channel, so that the accesspoint performs resource scheduling on the station according to therequest to send frame.

The processing module 123 is further configured to: select at least oneidle channel or idle sub-channel from the random competition channelaccording to the allocation information of the available channels if thedetermining module 122 determines that the station is not theto-be-scheduled station.

The sending module 124 is further configured to send a request to sendframe by using the selected idle channel or idle sub-channel.

Further, the station 12 may further include a detection module 125,configured to: if the determining module 122 determines that the stationis the to-be-scheduled station, detect whether cached data exists on thestation; and if it is detected that cached data exists, trigger theprocessing module 123 to determine the corresponding used-for-schedulingchannel according to the allocation information of the availablechannels.

Still further, the device indication information is further used toindicate the non-to-be-scheduled station. If the station is not theto-be-scheduled station, the determining module 122 is furtherconfigured to: determine, according to the device indicationinformation, whether the station is the non-to-be-scheduled station, andif it is determined that the station is the non-to-be-scheduled station,trigger the processing module 123 to select the at least one idlechannel or idle sub-channel from the random competition channel.

Yet further, the sending module 124 is further configured to startwaiting when the receiving module 121 receives the control frame, andsend, by using the determined used-for-scheduling channel, the requestto send frame only when waiting duration is equal to preset duration.

It can be understood that a function of each function module of theaccess point 12 in this embodiment can be specifically implementedaccording to the methods in the foregoing method embodiments. Forspecific descriptions, correspondingly refer to related descriptions ofthe method embodiments in FIG. 8 and FIG. 9, and details are notdescribed herein again.

Referring to FIG. 13, FIG. 13 is a schematic structural diagram ofanother station according to an embodiment of the present invention. Asshown in FIG. 13, the station 13 may include at least one processor 131,for example, a CPU, at least one communications bus 132, a radio signaltransceiver apparatus 133, and a memory 134. The radio signaltransceiver apparatus 133 is configured to receive and send a signal,such as a control frame or a request to send frame. The communicationsbus 132 is configured to implement connection and communication amongthese components. The memory 134 may be a high-speed, or may be anon-volatile memory (non-volatile memory), for example, at least onemagnetic disk memory. The memory 134 stores a set of program code. Theprocessor 131 is configured to invoke the program code stored in thememory 134, to perform the following operations: receiving, by using theradio signal transceiver apparatus 133, a control frame sent by anaccess point, where the control frame includes device indicationinformation and allocation information of available channels, the deviceindication information is used to indicate a to-be-scheduled station,and the allocation information includes information about aused-for-scheduling channel allocated to each to-be-scheduled stationand information about a selectable random competition channel allocatedto a non-to-be-scheduled station; determining, according to the deviceindication information, whether the station is the to-be-scheduledstation; and if yes, determining, by the station, a correspondingused-for-scheduling channel according to the allocation information ofthe available channels, and sending a request to send frame by using thedetermined used-for-scheduling channel; or if no, selecting at least oneidle channel or idle sub-channel from the random competition channelaccording to the allocation information of the available channels, andsending a request to send frame by using the selected idle channel oridle sub-channel.

Further, if the station is the to-be-scheduled station, the processor131 may further perform the following operation before determining thecorresponding used-for-scheduling channel according to the allocationinformation of the available channels: determining that cached dataexists on the station.

Still further, the device indication information is further used toindicate the non-to-be-scheduled station. If the station is not theto-be-scheduled station, the processor 131 may further perform thefollowing operation before selecting the at least one idle channel oridle sub-channel from the random competition channel according to theallocation information of the available channels: determining, accordingto the device indication information, that the station is thenon-to-be-scheduled station.

Yet further, the processor 131 may further perform the followingoperation: starting waiting upon receiving the control frame, andsending the request to send frame only when waiting duration is equal topreset duration.

It can be understood that a function of each function module of theaccess point 13 in this embodiment can be specifically implementedaccording to the methods in the foregoing method embodiments. Forspecific descriptions, correspondingly refer to related descriptions ofthe method embodiments in FIG. 8 and FIG. 9, and details are notdescribed herein again.

Referring to FIG. 14, FIG. 14 is a schematic structural diagram of asystem for obtaining a request of a station according to an embodimentof the present invention. The system for obtaining a request of astation according to this embodiment of the present invention includesan access point and at least one station. N in FIG. 14 represents aquantity of station s, and N is an integer. For the access point, referto the embodiments corresponding to FIG. 10 and FIG. 11. For thestation, refer to the embodiments corresponding to FIG. 12 and FIG. 13.Details are not described herein again.

An embodiment of the present invention further provides a computerstorage medium. The computer storage medium stores a program. Duringexecution of the program, some or all of the steps in the methodsdescribed with reference to FIG. 1 to FIG. 7 in the embodiments of thepresent invention are executed.

An embodiment of the present invention further provides a computerstorage medium. The computer storage medium stores a program. Duringexecution of the program, some or all of the steps in the methodsdescribed with reference to FIG. 8 and FIG. 9 in the embodiments of thepresent invention are executed.

Sequence adjustment, combination, and deletion may be performed on thesteps of the methods in the embodiments of the present inventionaccording to an actual need.

Combination, division, and deletion may be performed on the modules ofthe apparatuses in the embodiments of the present invention according toan actual need.

In descriptions in this specification, descriptions about such referenceterms as “an embodiment,” “some embodiments,” “an example,” “a specificexample,” and “some examples” mean that specific features, structures,materials, or characteristics described with reference to theembodiments or examples are included in at least one embodiment orexample of the present embodiments. In this specification, theillustrative descriptions about the foregoing terms do not necessarilyconcern a same embodiment or example. In addition, the describedspecific features, structures, materials, or characteristics may becombined in a proper manner in any one or more of the embodiments orexamples. In addition, persons skilled in the art may integrate orcombine different embodiments or examples and characteristics ofdifferent embodiments or examples described in this specification, aslong as they do not conflict with each other.

In addition, the terms “first” and “second” are merely intended for apurpose of description, and shall not be understood as an indication orimplication of relative importance or an implicit indication of aquantity of indicated technical features. Therefore, a feature limitedby “first” or “second” may explicitly or implicitly include at least oneof the features. In the descriptions about the present embodiments,“multiple” means at least two, for example, two or three, unlessotherwise specifically limited.

Descriptions about any process or method described in a flowchart or inanother manner herein may be understood as indicating that one or moremodules, segments, or parts of code that can execute an instruction andthat is used to implement a specific logical function or a step of aprocess are included, the scope of preferred implementations of thepresent embodiments includes other implementation, and functions may beperformed in a sequence other than a shown or discussed sequence,including in a generally simultaneous manner or a reverse sequenceaccording to the functions concerned. This should be understood bypersons skilled in the technological field to which the embodiments ofthe present invention belong.

Logic and/or steps, for example, program lists of executableinstructions regarded as configured to implement logical functions,indicated in flowcharts or described herein in another manner can bespecifically implemented in any computer readable medium, so as to beused by an instruction-executing system, apparatus, or device (forexample, a computer-based system, a system that includes a processor, oranother system that can obtain an instruction from aninstruction-executing system, apparatus, or device and execute theinstruction), or be used in combination with the instruction-executingsystem, apparatus, or device. With respect to this specification, the“computer readable medium” may be any apparatus that can include, store,communicate, propagate, or transmit a program so that the program can beused by the instruction-executing system, apparatus, or device or beused in combination with the instruction-executing system, apparatus, ordevice. More specific examples (a non-exhaustive list) of the computerreadable medium include the following: an electrical connection part (anelectronic apparatus) that has one or more laid wires, a portablecomputer disk box (a magnetic apparatus), a random access memory (RAM),a read-only memory (ROM), an erasable programmable read only memory(EPROM or a flash memory), an optical fiber apparatus, and a portablecompact disc read-only memory (CDROM). In addition, the computerreadable medium may even be a paper on which the program can be printedor another suitable medium. This is because the program can be obtainedin an electronic manner by performing optical scanning on the paper orthe another medium and then performing edition and decoding, or byperforming processing in another proper manner when necessary, and thenthe program is stored in a computer memory.

Persons of ordinary skill in the art may understand that all or some ofthe steps of the methods in the foregoing embodiments may be implementedby a program instructing related hardware. The program may be stored ina computer readable storage medium. During execution of the program, oneor a combination of the steps of the method embodiments is performed.

In addition, functional units in the embodiments of the presentinvention may be integrated into one processing module, or each unit mayexist alone physically, or two or more units may be integrated into onemodule. The integrated module may be implemented in a form of hardware,or may be implemented in a form of a functional module of software. Ifthe integrated module is implemented in a form of a functional module ofsoftware and is sold or used as an independent product, the integratedmodule may be stored in a computer readable storage medium.

The foregoing storage medium may be a read-only memory, a magnetic disk,an optical disk, or the like. Although the embodiments of the presentinvention are shown and described above, it can be understood that theforegoing embodiments are examples and cannot be understood as alimitation on the present embodiments. Within the scope of the presentembodiments, persons of ordinary skill in the art may make changes,modifications, replacement, and variations to the foregoing embodiments.

What is claimed is:
 1. An access point comprising: a processor; atransceiver configured to communicate with the processor through aninternal connection; wherein the processor is configured to execute aprogram to: construct a control frame, wherein the control framecomprises to-be-scheduled station user information andnot-to-be-scheduled station user information, the to-be-scheduledstation user information comprises indication information indicating ato-be-scheduled station and allocation information of a part ofsub-channel of the available channel allocated to the to-be-scheduledstation, the not-to-be-scheduled station user information comprisesindication information indicating a not-to-be-scheduled station andallocation information of another part of sub-channel of the availablechannel allocated to the not-to-be-scheduled station; control thetransceiver to send the control frame.
 2. The access point of claim 1,wherein the indication information indicating the to-be-scheduledstation comprises identifier information of the to-be-scheduled station.3. The access point of claim 1, wherein the transceiver is furtherconfigured to receive a requests to send frame that requests to send,the requests to send frame being sent from a station after sending thecontrol frame; and the program includes further instructions that causethe processor to perform resource scheduling according to the requeststo send frame.
 4. The access point according to claim 1, wherein theto-be-scheduled station user information comprises first userinformation and second user information, the first user informationcomprises first indication information indicating a firstto-be-scheduled station and first allocation information of a firstsub-channel in a part of sub-channel of the available channel allocatedto the first to-be-scheduled station, the second user informationcomprises second indication information indicating a secondto-be-scheduled station and second allocation information of a secondsub-channel in a part of sub-channel of the available channel allocatedto the second to-be-scheduled station.
 5. The access point according toclaim 1, wherein the available channel comprises one idle channel, andwherein the program includes further instructions that cause theprocessor to allocate a part of sub-channel of the one idle channel tothe to-be-scheduled station, and allocate the other part of sub-channelof the one idle channel to the not-to-be-scheduled station.
 6. Theaccess point according to claim 1, wherein the available channelcomprises at least two idle channels, and wherein the program includesfurther instructions that cause the processor to allocate a part ofsub-channel of the at least two idle channels to the to-be-scheduledstation, and allocate the other part of sub-channel of the at least twoidle channels to the not-to-be-scheduled station.
 7. The access pointaccording to claim 1, wherein the available channel comprises at leasttwo idle channels, and wherein the program includes further instructionsthat cause the processor to allocate a part of sub-channel of eachchannel of the at least two idle channels to the to-be-scheduledstation, and allocate the other part of sub-channel of each channel ofthe at least two idle channels to the not-to-be-scheduled station.
 8. Astation comprising: a processor; a transceiver configured to communicatewith the processor through an internal connection; wherein the processoris configured to execute a program to control the transceiver to:receive a control frame, wherein the control frame comprisesto-be-scheduled station user information and not-to-be-scheduled stationuser information, the to-be-scheduled station user information comprisesindication information indicating a to-be-scheduled station andallocation information of a part of sub-channel of the available channelallocated to the to-be-scheduled station, the not-to-be-scheduledstation user information comprises indication information indicating anot-to-be-scheduled station and allocation information of another partof sub-channel of the available channel allocated to thenot-to-be-scheduled station; and send a frame that requests to sendaccording to the control frame.
 9. The station to claim 8, wherein theindication information indicating the to-be-scheduled station comprisesidentifier information of the to-be-scheduled station.
 10. The stationto claim 8, wherein the program includes further instructions that causethe processor to make the transceiver to when the station is theto-be-scheduled station, send a frame that requests to send by the partof sub-channel of the available channel.
 11. The station to claim 8,wherein the program includes further instructions that cause theprocessor to make the transceiver to when the station is thenot-to-be-scheduled station, sends a frame that requests to send byanother part of sub-channel of the available channel.
 12. The station toclaim 8, wherein the program includes further instructions that causethe processor to make the transceiver to receive resource schedulingafter sending the frame that requests to send.